KR850001283B1 - Housing for an electro-magnetic stirrer coil - Google Patents

Abstract

The copper wall (1) of a mold having the form of a quadrilateral column is composed of four thin copper paltes(1a),(1a'), (1b)(1b'). Supports(2a),(2a'),(2b),(2b') are fixed on the side planes and hold up the copper plates(1a),(1a'),(1b),(1b'). A passage for cooled medium(S10) is formed between the supports and copper plates. This mold, with an electro-magnetic stirrer coil, is composed of a pair of supporting frames(4a),(4b) to uphold the supports(2a),(2a'),(2b) ,(2b') and space to palce the electromagnetic stirrer coil(9), which is formed between the supports and supporting frames(4a),(4b).

Description

Molds with electromagnetic stirring coils for continuous casting equipment

FIG. 1 is a cross sectional view of the half of the electromagnetic stirring mold taken along line I-I of FIG. 4. FIG.

2 is a cross-sectional view of the right and left sides taken along the line II-II of FIG.

3 is a cross-sectional view of the right and left sides taken along the line III-III of FIG. 4;

4 is a cross-sectional view of the right and left sides taken along the line IV-IV of FIG.

5 is a cross-sectional view of the right and left sides taken along the line VV of FIG.

FIG. 6 is a partial cross-sectional view showing a portion of FIG. 1. FIG.

The present invention relates to a mold equipped with an electromagnetic stirring coil for a continuous casting device.

Recently, continuous casting apparatus designed to produce high grade steel has an electromagnetic stirrer to increase flow of molten steel in a copper wall mold to increase isotropic crystals and satisfactorily float the inclusions.

This type of electromagnetic stirrer is based on the principle of an induction motor, and has an electromagnetic coil disposed around the copper wall of the mold to generate a rotating magnetic field, thereby giving flow motion to the molten steel in the copper wall mold.

Conventional molds are formed with a glass plate having a predetermined thickness to prevent thermal expansion bending of the mold wall due to molten steel, but the use of a large thickness copper plate reduces the magnetic investment of magnetic force generated by an electromagnetic coil disposed around the mold. This results in a fatal disadvantage that electromagnetic stirring of molten steel in the mold is not effective.

The present invention has the provision of a mold using an electromagnetic coil for achieving the above problems in the conventional mold and for the efficient electromagnetic stirring of molten steel, the mold being arranged to make the installation of the electromagnetic coil easy and the whole apparatus small.

The first aspect of the present invention is a quadrilateral columnar copper mold wall composed of four thin flat copper plates, and support plates bonded to each other at their side surfaces to support the copper plates. And a pair of support frames for supporting the support plates therebetween, and a space for installing electromagnetic coils formed between the support plates and the support frames.

This form of the invention is described in detail below.

The present invention will be described in more detail with reference to the accompanying drawings.

The mold copper wall 1 is composed of four thin flat copper plates 1a, 1a ', 1b, and 1b'. In this embodiment, the pair of copper plates 1b and 1b 'are narrow while the other pair of copper plates 1a and 1a' are wide. Each of the narrow steel sheets 1b and 1b 'has an end surface 1d in contact with an end surface 1e of the protrusion 1c that forms the rounded corner of the quadrilateral copper wall.

The steel sheets 1a, 1a ', 1b, and 1b' are supported by supporting plates 2a, 2a ', 2b, and 2b' which are nonmagnetic materials, respectively. In particular, as shown in Figs. 2 to 5, each support plate has a number of bolt holes 3a, while each copper plate is secured to its rear end at a position coincident with the bolt hole 3a above. 3) is inserted into this stud bolt hole 3a and tightened with a nut. The bolt hole 3a has a diameter large enough to allow the stud bolt to move in accordance with the thermal expansion of the copper plate.

Each backing plate is perpendicular to the surface facing the copper plate joined for check between the water passages S ₁₆ , S ₉ extending in a plurality of width directions at the top and bottom and the upper and lower passages S ₁₆ , S ₉ . Has a water passage (S ₁₀ ).

The opposite side of each support plate is corrugated as shown in Figs. 2 and 5, and the ridge 2c on the face of each copper plate is received (by gripping) in the groove 2d of the adjacent copper plate face. As shown in FIG. 2, the bolt 5 is inserted into the hole 5a in the ridge 2c and screwed into the groove 2d. Each bolt 5 has a dish-like spring 6 fitted therein to allow movement of the base plate at a slight right angle. In addition, the holes 5a, such as the bolt holes 3a, have a diameter larger than the diameter of the bolts 5 so that adjacent receiving plates can be moved slightly perpendicular to each other.

In the manner described above, the supporting plates 2a, 2a ', 2b, and 2b' are assembled so that the opposite end surfaces 1d of the pair of wide copper plates 1a and 1a 'are paired narrow. It is pressed against the end surface 1e of the ridge on the copper plates 1b and 1b ', and the pair of narrow copper plates 1b and 1b' oppose the end surfaces 1f of the pair of wide copper plates ( The back of 1a) and 1a 'is pressed against a pair of wide support plates 2a and 2a', and the back of a pair of narrow copper plates 1b and 1b 'is a pair of support plates 2b. And 2b '.

A space for mounting the electromagnetic coil 9 is provided between the outer circumference of the support plate 2 assembled in the form of a quadrilateral prism described above and between the supporting frames 4a, 4b to be described later. The electromagnetic coil 9 installed in this space is supported from below by a bracket 2c 'provided at the bottom of the back of the backing plate. Moreover, reference numeral 9a shown in FIG. 2 and FIG. 3 indicates the connection portion of the electromagnetic coil 9.

As shown, the height of the space for mounting the electromagnetic coil 9 is smaller than the height of the backing plate 2 so that the top and bottom of the backing plate 2 extend beyond the electromagnetic coil 9.

The pair of narrow backing plates 2b, 2b 'has an upper water passage box 8a attached to the upper portion of its rear side with the bolt 11, as shown in FIGS. 1 and 6, As shown in the figure, it has a lower bucket passage box 8b attached to the lower portion of the back of the bolt 11. The fixing wall 8b of the upper passage box 8a in contact with the supporting plates 2b and 2b 'is connected to the upper passage passage S ₂₇ of the supporting plates 2b and 2b'. Has (S ₂₇ ). Furthermore, the fixed wall 8d of the lower water passage box 8b in contact with the support plates 2b and 2b 'is connected to the water passage hole S ₉ of the lower water passage holes S ₉ of the support plates 2b and 2b'. It has a hole S ₁₅ .

The base plate 2 provided with the electromagnetic coil 9 and the upper water passage boxes 8a, 8a 'and the lower water passage boxes 8b, b' around the outside is provided with a pair of supporting frames 4a, ( 4b).

As shown in FIG. 3, the pair of support frames 4a and 4b have a pair of wide support plates for the upper and lower tubular portions 4c and 4d forming the water passages S ₄ and S ₇ . With the end walls 4e of boxes 4c and 4d adjacent to the upper and lower regions of the back of 2a) and 2b, the assembly is supported by four support rods 10. As shown well in FIGS. 2 and 5, each support rod 10 has a dish-like spring 6 fitted at its opposite end, which is supported on a seat 10a. In this way, when the narrow copper plates 1b and 1b 'thermally expand in the width direction to cause external movement of the wide support plates 2a and 2a' to the right angle, a pair of support frames 4a and 4b ) Permits expansion due to contraction of the disc spring (6).

The support frames 4a and 4b respectively have upper and lower bucket passages S ₄ and S ₇ and a plurality of bucket passages or bucket passage holes. In particular, as shown in FIG. 2 and FIG. 4, these are the water passage holes 4 formed in the outer wall 4g of the support frames 4a and 4b, and the water passages S connected to the water passage holes 4 described above. ₅ ) and the water passage (S ₆ ) connected to the water passage (S ₅ ) and extends down from the bent passage to be connected to the water passage (S ₇ ). Figure 2 shows another part on both sides of the central axis 0, but the waterway relationship is symmetric about the central axis zero. The support frame is a water passage S ₁₇ of the end wall 4e of the upper box portion 4c connected to the upper passage hole S ₁₆ in the wide support plates 2a and 2b and the wide support plate 2a. And a communication hole S ₈ connected to the lower water passage hole S ₁₉ of (2b). Here, the water passages S _{19 on} both sides of the end wall 4e of the upper box portion 4c and the water passages S _{11 on} both sides of the end wall 4e of the lower box portion 4d are provided. have.

The water passage S _{19 is} connected to the water passage S ₂₀ of the upper melbox part 8a through the block 7 having the water passage S ₂₀ , while the water passage S ₁₁ is connected to the water passage S ₁₁ . It is connected to the water passage S ₁₃ of the lower water passage box portion 8b through the block 7 having S ₁₂ ). In addition, the connection to the block (7) is U- no matter how the upper and lower water passage box portion (8a, 8b) and the support frame (4a), (4b) moves in any direction with respect to the block (7) The seal is maintained by using a sealing member such as a packing.

As described above, the pair of support frames 4a, 4b having the supporting plates 2 supported therebetween are made up by a pair of hanger frames 12a, 12b. The hanger frames 12a and 12b are installed on the mold stand (not shown) of the continuous casting apparatus.

This embodiment is configured with a pair of hanger frames to mount the support frame to install the mold, but the opposite end of the support frame may be modified to provide a cooling passage and the mold installation therein. For example, opposite ends of the support frame have an extension that extends parallel to the backing plates 2b, 2b 'and has a shape similar to a hanger board to be described later. The support frames 4a and 4b of the present embodiment are designed such that the side walls 4g are fixed to the side walls 12c of the hanger frames 12a and 12b with bolts 14. This state is well illustrated in FIG. However, this fixing is performed by considering that the support frames 4a, 4b move while the copper walls 1 undergo thermal expansion as described above. Allow some movement with respect to (12b).

In particular, the bolt holes 14a of the hanger frames 12a and 12b are long and the bolts 15 tightened to the side walls 4g of the support frame are supported with respect to the hanger frames 12a and 12b. It moves to some extent with (4b).

In addition, the upper water passage box portion 8a installed on the narrow support plates 2b and 2b 'is fixed to the hanger frame with bolts 15. However, when the bolt 14 is fixed by the bolt 14, the bolt hole 15 of the upper passage box portion 8a is long so that the upper passage passage box 8a is narrow when the copper wall 1 is thermally expanded. ), Can be moved together with (2b ').

The pair of hanger frames 12a and 12b have a water passage box portion 12d at the upper portion, a plurality of water passages and a water passage hole therein, and their arrangement is in a point symmetrical relationship.

As shown in FIG. 2, the water passage boxes 12d of the hanger frames 12a and 12b each have a partition 12f for dividing the water passages S ₂ and S ₂₅ . Has a water passage (S ₂ ). The water passage S ₂ is connected to the water passage hole S ₁ through which the coolant is introduced, and is also connected to the branched water passages S _2-1 and S _2-2 . In this case, if it provides a connection to the water supply connection on the mold mounting of the part of the hanger frame corresponding to the front end of the water passage hole S ₁ , this simplifies the mold installation and reduces the cost. Water passages (S _2-1 , S _2-2 ) are connected to the water passages (S _2-1 , S _2-2 ) formed in the side wall (12c), respectively, while the water passages (S _2-1) , S _2-2 is connected to the water passage hole S ₄ formed in the side walls 4g of the support frames 4a and 4b. As shown in FIG. 6, another water passage S ₃₅ has a water passage hole 24 connected to the water passage hole S ₂₃ formed in the upper water passage box portion 8a, as shown in FIG. As shown in the drawing, the water passage has a hole S ₂₆ for cooling water discharge.

The configuration of the mold according to the present embodiment is as described above, and the cooling water flows as follows.

The coolant flows into the water passage S ₂ via the water passage hole S _{1 in} the water passage box portion 12d of the hanger frames 12a and 12b and flows into the water passage S _2-1 and S _{2. -2} ) and flows to the water passage (S ₅ ) via the water passage holes (S _2-1 , S _2-2 ) and the water passage holes (S ₄ ) in the support frames (4a), (4b). Flow.

Cooling water enters the water bottle in the following flows down through the (S ₆₎ in the bucket, the support frame (4a, 4b) lower passage box part (4d) of a (S _7). The coolant then passes through the water passage holes S ₈ and the water passage holes S ₉ of the wide support plates 2a and 2a ', or through the water passage holes S ₁₁ and the water passage S in the block &. ₁₂ ), through the water passage (S ₁₃ , S ₁₄ ) in the lower water passage box portion 8b, the water passage hole S ₁₅ and the water passage hole S _{9 in the} narrow support plates 2b and 2b '. Flows into the lower part of the water passage (S ₁₀ ), from which the coolant flows upward through the water passage (S ₁₀ ), and then the water passage hole (S ₁₆ ) and the narrow support plate in the wide support plates (2a) and (2a '). (2b), (2b ') enters the water passage (S ₁₈ ) through the water passage hole (S ₁₇ ) in the upper water passage box portion (4c), while the cooling water is narrow support plate (2b), (2b') The water passage S ₂₂ is entered through the water passage hole S ₁₆ and the water passage hole S _{27 in the} upper water passage upper bottom 8a. Cooling water in a water bottle (S ₂₂₎ flows through the holes (S ₂₂₎ to the water basin, via a hanger plate (12a), the hole in the bucket a bucket in the box part (12d) of (12b) (S _24), a water basin It enters the hole S ₂₅ and is discharged through the water passage hole S ₂₆ therefrom.

Moreover, the cooling of the electromagnetic coil itself is effected by winding the coil hollow and passing the coolant through the cavity space.

As will be apparent from the detailed description of the above embodiment, since the apparatus is equipped with an electromagnetic stirring coil for the continuous casting apparatus according to the present invention, or because a suitable mold is assembled into a mold copper wall, a backing plate, etc., since it is a separate component rather than integrated, It is very easy to manufacture and inexpensive. The support provided by the backing plate thins the mold copper wall and eliminates the difficulty of electromagnetic stirring. In addition, since a space for mounting the electromagnetic coil is provided between the support plate and the support frame, the installation of the electromagnetic coil is extremely easy, and the mold is miniaturized.

Claims (1)

A quadrilateral prismatic cast copper wall (1) consisting of four flat thin copper plates (1a), (1a '), (1b)' (1b '), and a support plate (2a) fixed to the side thereof to support the copper plate. (2a '), (2b), (2b') A pair of support frames 4a and (2a) for supporting the cooling medium passage S ₁₀ formed between the support plate and the copper plate, and the support plate therebetween. 4b) and a mold provided with an electromagnetic stirring coil for a continuous casting device, comprising a space for installing an electromagnetic stirring coil (9) formed between the support plate and the support frame.

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